EC:2.7.13.3 - FACTA Search

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Query: EC:2.7.13.3 (histidine kinase)
2,405 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

OmpR is a transcriptional activator for the expression of outer membrane porin genes ompF and ompC in Escherichia coli. Its C-terminal half has been identified as the DNA-binding domain (K. Tsung, R. Brissette, and M. Inouye, J. Biol. Chem. 264:10104-10109, 1989). Recent studies have indicated that the N-terminal non-DNA-binding domain of OmpR is involved in modulating OmpR function through interaction with the EnvZ protein, a kinase and phosphatase for OmpR. We isolated and characterized two mutations, G94D and E111K, in the N-terminal domain of OmpR and one mutation, R182C, in the DNA-binding domain of OmpR. All three mutations abolished the ability of OmpR to bind to the ompF and ompC promoters in vivo, thus giving an OmpF- OmpC- phenotype. The decreased DNA-binding ability of the mutant OmpRs was not due to diminished phosphorylation of their N termini, since all the mutant OmpRs were found to be normally phosphorylated by EnvZ in vitro. The mutant OmpRs produced from multicopy plasmids were also found to inhibit completely the production of OmpF and OmpC in wild-type cells, and the complete inhibition depended on the function of EnvZ which was produced in cis or in trans from plasmids. The relationship of the possible alterations in OmpR by the mutations with the observed diminished binding ability is discussed.
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PMID:Mutations in a central highly conserved non-DNA-binding region of OmpR, an Escherichia coli transcriptional activator, influence its DNA-binding ability. 132 Nov 17

Osmoregulated porin gene expression in Escherichia coli is controlled by the two-component regulatory system EnvZ and OmpR. EnvZ, the osmosensor, is an inner membrane protein and a histidine kinase. EnvZ phosphorylates OmpR, a cytoplasmic DNA-binding protein, on an aspartyl residue. Phospho-OmpR binds to the promoters of the porin genes to regulate the expression of ompF and ompC. We describe the use of limited proteolysis by trypsin and ion spray mass spectrometry to characterize phospho-OmpR and the conformational changes that occur upon phosphorylation. Our results are consistent with a two-domain structure for OmpR, an N-terminal phosphorylation domain joined to a C-terminal DNA-binding domain by a flexible linker region. In the presence of acetyl phosphate, OmpR is phosphorylated at only one site. Phosphorylation induces a conformational change that is transmitted to the C-terminal domain via the central linker. Previous genetic analysis identified a region in the C-terminal domain that is required for transcriptional activation. Our results indicate that this region is within a surface-exposed loop. We propose that this loop contacts the alpha subunit of RNA polymerase to activate transcription. Mass spectrometry also reveals an unusual dephosphorylated form of OmpR, the potential significance of which is discussed.
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PMID:Phosphorylation-dependent conformational changes in OmpR, an osmoregulatory DNA-binding protein of Escherichia coli. 756 33

In Escherichia coli, expression of the major outer membrane proteins, OmpC and OmpF, is regulated through the functions of OmpR and EnvZ at the transcriptional level in response to the medium osmolarity. OmpR is the crucial activator that helps RNA polymerase to efficiently trigger ompC and ompF transcription. This OmpR function is modulated by phosphorylation mediated by the cognate sensory kinase, EnvZ. Phosphorylation at the N-terminal domain of OmpR results in substantial enhancement of the DNA-binding ability of the C-terminal domain, thereby allowing the activation of ompC and ompF transcription by OmpR. Here we isolated an OmpR mutant which lacks the N-terminal half, but can enhance transcription in vivo. This novel type of OmpR mutant was revealed to have a single amino acid replacement of Gly227 to Cys. The newly-introduced-Cys residue allows OmpR molecules to form a stable dimer in vitro without the help of the N-terminal half. This altered C-terminal half is able to bind efficiently and specifically to the cognate DNA in vitro. It can function as an activator for ompC transcription in vitro in a phosphorylation-independent manner. These results suggest that the putative activator domain of OmpR, together with the DNA-binding domain, is most likely located in the C-terminal half. They also suggested that the phosphorylation of OmpR may not be essential for gene activation per se.
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PMID:Gene activation by the Escherichia coli positive regulator, OmpR. Phosphorylation-independent mechanism of activation by an OmpR mutant. 793 17

We have isolated mutants of Saccharomyces cerevisiae with an increased sensitivity to oxidative stress. All pos9 mutants (pos for peroxide sensitivity) were hypersensitive to methylviologene, hyperbaric oxygen or hydrogen peroxide, but grew similarly to the wild-type under all other conditions tested. Isolation and sequencing of the respective POS9 gene revealed that it was identical to SKN7. The predicted Skn7/Pos9 protein possesses a domain with high homology to prokaryotic response regulators. These regulatory proteins are part of a simple signalling cascade termed a "two-component system", where a phosphorylation signal of a histidine kinase is transferred to a conserved aspartate residue of the response regulator. To test the functional role of the respective aspartate residue of Skn7/Pos9 protein in oxidative stress, we mutagenized this residue in vitro to alanine, arginine and glutamate. Only the glutamate allele (D427 to E) was able to rescue the hydrogen peroxide-sensitivity of pos9 mutants. By fusion experiments with the Gal4 DNA-binding domain we identified the isolated response regulator-like domain as a novel eukaryotic domain sufficient for gene activation. Whereas this hybrid protein activated transcription of a lacZ reporter gene under aerobic conditions, no activation was observed under anaerobic conditions, indicating that the response regulator domain is involved in a signalling reaction. Two-hybrid investigations also suggest an oligomerization of the Pos9 protein. Our results indicate that a two-component system is involved in the oxidative-stress response of yeast.
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PMID:The response regulator-like protein Pos9/Skn7 of Saccharomyces cerevisiae is involved in oxidative stress resistance. 859 53

In bacteria and lower eukaryotes, adaptation to changes in the environment is often mediated by two-component regulatory systems. Such systems provide the basis for chemotaxis, nitrogen and phosphate regulation and adaptation to osmotic stress, for example. In Escherichia coli, the sensor kinase EnvZ detects a change in the osmotic environment and phosphorylates the response regulator OmpR. Phospho-OmpR binds to the regulatory regions of the porin genes ompF and ompC, and alters their expression. Recent evidence suggests that OmpR functions as a global regulator, regulating additional genes besides the porin genes. In this study, we have characterized a previously isolated OmpR2 mutant (V203M) that constitutively activates ompF and fails to express ompC. Because the substitution was located in the C-terminal DNA-binding domain, it had been assumed that the substitution would not affect phosphorylation of the N-terminal domain of OmpR. Our results indicate that this substitution completely eliminates phosphorylation by a small phosphate donor, acetyl phosphate, but not phosphorylation by the kinase EnvZ. The mutant OmpR has altered dephosphorylation kinetics and altered binding affinities to both ompF and ompC sites compared to the wild-type. Thus, a single amino acid substitution in the C-terminal DNA-binding domain has dramatic effects on the N-terminal phosphorylation domain. Most strikingly, we have identified a single base change in the OmpR binding site of ompC that restores high-affinity binding activity by the mutant. We interpret our results in the context of a model for porin gene expression.
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PMID:A single amino acid substitution in the C terminus of OmpR alters DNA recognition and phosphorylation. 1087 50

Signal transduction by two-component regulatory systems involves phosphorylation of the receiver domain of a response regulator by the transmitter domain of the cognate histidine kinase. In the NtrBC system, phosphorylation of NtrC by NtrB results in transcriptional activation of nitrogen-regulated genes. We have used the yeast two-hybrid system to probe interactions between domains of the NtrB and NtrC proteins from Klebsiella pneumoniae. We constructed fusions from each of a series of proteins or protein domains to the activation and the DNA-binding domains of GAL4 and analysed expression of GAL1:lacZ and GAL1:HIS3 reporters in yeast. The DNA-binding domain of NtrC and the so-called sensor domain of NtrB appeared to provide the major determinants for dimerization of the fusion proteins. A strong and specific interaction was also shown between NtrB and NtrC, localized to the HN region of the NtrB transmitter module and to the NtrC receiver domain, whereas other domains of these proteins do not appear to contribute to the recognition specificity. The results presented here indicate that communication between two-component partners also involves protein-protein interactions that can be detected in vivo, suggesting that the yeast two-hybrid system is a powerful genetic tool for identifying functional partners of prokaryotic signal transduction pathways.
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PMID:Two-hybrid analysis of domain interactions involving NtrB and NtrC two-component regulators. 1129 84

The archetypal two-component signal transduction systems include a sensor histidine kinase and a response regulator, which consists of a receiver CheY-like domain and a DNA-binding domain. Sequence analysis of the sensor kinases and response regulators encoded in complete bacterial and archaeal genomes revealed complex domain architectures for many of them and allowed the identification of several novel conserved domains, such as PAS, GAF, HAMP, GGDEF, EAL, and HD-GYP. All of these domains are widely represented in bacteria, including 19 copies of the GGDEF domain and 17 copies of the EAL domain encoded in the Escherichia coli genome. In contrast, these novel signaling domains are much less abundant in bacterial parasites and in archaea, with none at all found in some archaeal species. This skewed phyletic distribution suggests that the newly discovered complexity of signal transduction systems emerged early in the evolution of bacteria, with subsequent massive loss in parasites and some horizontal dissemination among archaea. Only a few proteins containing these domains have been studied experimentally, and their exact biochemical functions remain obscure; they may include transformations of novel signal molecules, such as the recently identified cyclic diguanylate. Recent experimental data provide the first direct evidence of the participation of these domains in signal transduction pathways, including regulation of virulence genes and extracellular enzyme production in the human pathogens Bordetella pertussis and Borrelia burgdorferi and the plant pathogen Xanthomonas campestris. Gene-neighborhood analysis of these new domains suggests their participation in a variety of processes, from mercury and phage resistance to maintenance of virulence plasmids. It appears that the real picture of the complexity of phosphorelay signal transduction in prokaryotes is only beginning to unfold.
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PMID:Novel domains of the prokaryotic two-component signal transduction systems. 1155 34

The initiation of sporulation in aerobic Bacillus species is regulated by the phosphorelay consisting of several sensor histidine kinases, the Spo0F response regulator, the Spo0B phosphotransferase and the Spo0A transcription factor that upon phosphorylation represses genes for growth and activates the developmental process. Clostridium species lack both Spo0F and Spo0B and the identities of the sensor histidine kinases are unknown. The amino acid sequence of Spo0A is highly conserved in Clostridium botulinum relative to Bacillus subtilis but the cloned C. botulinum Spo0A was unable to complement a spo0A mutant of B. subtilis for sporulation. However, it was able to repress the abrB gene of B. subtilis. Active site mutations in Spo0A still repressed, indicating this activity was independent of phosphorylation. An orphan sensor histidine kinase of C. botulinum appeared to normally phosphorylate C. botulinum Spo0A and expression of this kinase in combination with C. botulinum Spo0A in B. subtilis was lethal, suggesting phosphorylation of C. botulinum Spo0A repressed essential growth genes as a prerequisite to sporulation but could not compensate for this effect by inducing sporulation. A chimera Spo0A consisting of a B. subtilis Spo0A response regulator domain fused to a C. botulinum DNA-binding domain was capable of restoring sporulation to a spo0A mutant of B. subtilis albeit at less than wild-type levels. The data suggest that induction of sporulation requires interactions of both domains of Spo0A with other conserved proteins and despite the high conservation of the amino acid sequence of C. botulinum Spo0A, some of these interactions have been lost.
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PMID:Phosphorylation and functional analysis of the sporulation initiation factor Spo0A from Clostridium botulinum. 1642 Mar 67

Fungal pathogens of humans require molecular oxygen for several essential biochemical reactions, yet virtually nothing is known about how they adapt to the relatively hypoxic environment of infected tissues. We isolated mutants defective in growth under hypoxic conditions, but normal for growth in normoxic conditions, in Cryptococcus neoformans, the most common cause of fungal meningitis. Two regulatory pathways were identified: one homologous to the mammalian sterol-response element binding protein (SREBP) cholesterol biosynthesis regulatory pathway, and the other a two-component-like pathway involving a fungal-specific hybrid histidine kinase family member, Tco1. We show that cleavage of the SREBP precursor homolog Sre1-which is predicted to release its DNA-binding domain from the membrane-occurs in response to hypoxia, and that Sre1 is required for hypoxic induction of genes encoding for oxygen-dependent enzymes involved in ergosterol synthesis. Importantly, mutants in either the SREBP pathway or the Tco1 pathway display defects in their ability to proliferate in host tissues and to cause disease in infected mice, linking for the first time to our knowledge hypoxic adaptation and pathogenesis by a eukaryotic aerobe. SREBP pathway mutants were found to be a hundred times more sensitive than wild-type to fluconazole, a widely used antifungal agent that inhibits ergosterol synthesis, suggesting that inhibitors of SREBP processing could substantially enhance the potency of current therapies.
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PMID:A link between virulence and homeostatic responses to hypoxia during infection by the human fungal pathogen Cryptococcus neoformans. 1731 42

The Helicobacter pylori ArsS-ArsR two-component signal transduction system, comprised of a sensor histidine kinase (ArsS) and a response regulator (ArsR), allows the bacteria to regulate gene expression in response to acidic pH. We expressed and purified the full-length ArsR protein and the DNA-binding domain of ArsR (ArsR-DBD), and we analyzed the tertiary structure of the ArsR-DBD using solution nuclear magnetic resonance (NMR) methods. Both the full-length ArsR and the ArsR-DBD behaved as monomers in size exclusion chromatography experiments. The structure of ArsR-DBD consists of an N-terminal four-stranded beta-sheet, a helical core, and a C-terminal beta-hairpin. The overall tertiary fold of the ArsR-DBD is most closely related to DBD structures of the OmpR/PhoB subfamily of bacterial response regulators. However, the orientation of the N-terminal beta-sheet with respect to the rest of the DNA-binding domain is substantially different in ArsR compared with the orientation in related response regulators. Molecular modeling of an ArsR-DBD-DNA complex permits identification of protein elements that are predicted to bind target DNA sequences and thereby regulate gene transcription in H. pylori.
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PMID:Structural analysis of the DNA-binding domain of the Helicobacter pylori response regulator ArsR. 1911 56

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